Method and apparatus for compressed sensing

ABSTRACT

Method and apparatus for compressed sensing yields acceptable quality reconstructions of an object from reduced numbers of measurements. A component x of a signal or image is represented as a vector having m entries. Measurements y, comprising a vector with n entries, where n is less than m, are made. An approximate reconstruction of the m-vector x is made from y. Special measurement matrices allow measurements y=Ax+z, where y is the measured m-vector, x the desired n-vector and z an m-vector representing noise. “A” is an n by m matrix, i.e. an array with fewer rows than columns. “A” enables delivery of an approximate reconstruction, x #,  of x. An embodiment discloses approximate reconstruction of x from the reduced-dimensionality measurement y. Given y, and the matrix A, x #  of x is possible. This embodiment is driven by the goal of promoting the approximate sparsity of x # .

BACKGROUND OF THE INVENTION

1. Technical Field

The invention relates to the processing of digital information. More particularly, the invention relates to a method and apparatus for allowing acceptable-quality reconstruction of a signal, image, spectrum, or other digital object of interest.

2. Discussion of the Prior Art

In many fields of science and technology, it is desired to obtain information about a subject by measuring a digital signal which represents that subject. Examples include: Medical imaging (see F. Natterer, The Mathematics of Computerized Tomography, J. Wiley (1986); C. L. Epstein Introduction to the mathematics of medical imaging, Upper Saddle River, N.J.: Pearson Education/Prentice Hall (2003)), Mass Spectrometry (see A. Brock, N. Rodriguez, R. N. Zare, Characterization of a Hadamard transform time-of-flight mass spectrometer, Review of Scientific Instruments 71, 1306. (2000); P. Jansson, Deconvolution: with applications in spectroscopy, New York: Academic Press (1984)), NMR Spectroscopy (see J. Hoch, A. Stern, NMR Data Processing. Wiley-Liss, New York (1998)), and Acoustic Tomography (see J. Claerbout, Imaging the Earth's Interior, Blackwell Scientific Publications, Inc. (1985)). In these different cases, the measurements are intended to allow the construction of images, spectra, and volumetric images depicting the state of the subject, which may be a patient's body, a chemical in dilution, or a slice of the earth. Many other examples can be given in other fields.

Time and effort are involved in capturing data about the underlying object. For example, it can take time to perform an MRI scan of a patient, it can take time to perform a 3D CT scan of a patient, it can take time to measure a 3D NMR spectrum, it can take time to conduct a 3D seismic survey.

In all cases, it would be highly desirable to obtain acceptable-quality reconstruction of the desired image, spectrum, or slice with fewer measurements and consequently less measurement time. The benefits could translate into less cost, more system throughput, and perhaps less radiation dosage, depending on the specifics of the system under study and the sensor characteristics.

In each of such fields there is a currently-accepted practice for the number of measurements required to obtain a faithful rendering of the object of interest (see F. Natterer, The Mathematics of Computerized Tomography, J. Wiley (1986); J. R. Higgins, Sampling theory in Fourier and signal analysis: foundations, Oxford: New York: Clarendon Press; Oxford University Press (1996)). This accepted number of measurements sets the scale for the effort and cost required to obtain adequate information.

What would be highly desirable would be to have a system comprising methods to make reduced numbers of measurements compared to current practice and still give acceptable quality reconstructions of the object of interest.

SUMMARY OF THE INVENTION

The invention provides a method and apparatus for making reduced numbers of measurements compared to current practice and still give acceptable quality reconstructions of the object of interest.

In one embodiment, a digital signal or image is approximated using significantly fewer measurements than with traditional measurement schemes. A component x of the signal or image can be represented as a vector with m entries; traditional approaches would make m measurements to determine the m entries. The disclosed technique makes measurements y comprising a vector with only n entries, where n is less than m. From these n measurements, the disclosed invention delivers an approximate reconstruction of the m-vector x.

In another embodiment, special measurement matrices called CS-matrices are designed for use in connection with the embodiment described above. Such measurement matrices are designed for use in settings where sensors can allow measurements y which can be represented as y=Ax+z, with y the measured m-vector, x the desired n-vector and z an m-vector representing noise. Here, A is an n by m matrix, i.e. an array with fewer rows than columns. A technique is disclosed to design matrices A which support delivery of an approximate reconstruction of the m-vector x, described above.

Another embodiment of the invention discloses approximate reconstruction of the vector x from the reduced-dimensionality measurement y within the context of the embodiment described above. Given the measurements y, and the CS matrix A, the invention delivers an approximate reconstruction x^(#) of the desired signal x. This embodiment is driven by the goal of promoting the approximate sparsity of x^(#).

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 shows an example of compressed sensing in action.

DETAILED DESCRIPTION OF THE INVENTION

The reader of this document is assumed to be familiar with the standard notation of linear algebra, in particular the notions of matrices, (column) vectors, matrix-vector product, systems of linear equations (see G. H. Golub, C. F. Van Loan, Matrix Computations.. Baltimore: Johns Hopkins University Press (1983); P. Gill, W. Murray, M. Wright, Numerical linear algebra and optimization. Redwood City, Calif.: Addison-Wesley Pub. Co. (1991)). The reader is also assumed to be familiar with standard notions in large-scale scientific computing and engineering computation: these include linear programming (see P. Gill, W. Murray, M. Wright, Numerical linear algebra and optimization. Redwood City, Calif.: Addison-Wesley Pub. Co. (1991)), quadratic programming, iterative solution of linear systems (see A. Greenbaum, Iterative methods for solving linear systems, Frontiers in Applied Mathematics 17, SIAM, Philadelphia, Pa. (1997)), and related ideas. The required background can be obtained by reading books associated with college courses in linear algebra and/or matrix analysis, and by reading books associated with courses in optimization and in large-scale scientific computing. It may also be useful to have familiarity with signal processing (see S. Mallat, A Wavelet Tour of Signal Processing.. Second edition. Academic Press (1999)) and with the notion that certain sensors operate by acquiring linear combinations of signal elements (see F. Natterer, The Mathematics of Computerized Tomography, J. Wiley (1986); C. L. Epstein Introduction to the mathematics of medical imaging, Upper Saddle River, N.J.: Pearson Education/Prentice Hall (2003); P. Jansson, Deconvolution: with applications in spectroscopy, New York: Academic Press (1984); J. Hoch, A. Stern, NMR Data Processing. Wiley-Liss, New York (1998); and J. Claerbout, Imaging the Earth's Interior, Blackwell Scientific Publications, Inc. (1985)).

The Invention

Herein disclosed is a method and apparatus for allowing acceptable-quality reconstruction of a signal, image, spectrum or other digital object of interest. The preferred embodiment requires reduced numbers of measurements about the object as compared to standard measurement methods.

The object of interest is assumed to be representable as a vector x with m entries. The m entries correspond to data obtainable by standard methods of measurement.

The disclosed method and apparatus makes measurements yielding a vector y with n entries. Here n<m, corresponding to reduced numbers of measurements. The disclosed method and apparatus then delivers an approximation to x by a subsequent processing step known as reconstruction.

The method and apparatus therefore comprises two particular components which must be combined:

-   (1) Measurement Matrix. Associated with a realization of the     invention is an n by m matrix A. The proposed measurements y obey     the equations y=Ax+z, where Ax denotes the standard matrix-vector     product and z denotes noise. -   (2) Reconstruction procedure. Associated with the invention is an     algorithm which, given a vector y with n entries and a matrix A with     n times m entries, delivers an approximate solution x^(#)obeying y=A     x^(#)+e, with e the reconstruction error.

Each system component is discussed below in turn.

Measurement Matrices

The invention involves matrices A which are n by m numerical arrays and which define the measurements of the system. It is not the case that an arbitrary matrix may be used, however, there is a large supply of matrices which might be used. We will call the matrices which may be used CS-matrices, (CS=Compressed Sensing).

It is proposed that in a preferred embodiment of the invention, the sensor technology should be deployed in such a way that the measured vector y is (perhaps a noisy version of) Ax. The CS matrix A is in general a dense matrix, with all entries nonzero, and the operation Ax gives outputs which in general mix together all the entries of x.

A CS matrix A has the following character: it can be represented as a matrix product A=U B where B is p by m and U is n by p. In the preferred embodiment, p is equal to m, so that B is a square matrix. However, other values of p can be of interest in some applications (in which case typically p>m). In the preferred embodiment, B is a matrix with the property that, for typical objects of interest, i.e. images, spectra, etc. Bx is sparse or is approximately a sparse vector. In the preferred embodiment, B is an orthogonal matrix, although this can be relaxed in many applications.

In the preferred embodiment, U is an n by p matrix with the properties that:

-   (1) the columns of U are of unit length in the Euclidean norm; -   (2) the square matrix G=U′U, where U′ denotes the transpose     (real-valued matrix entries) or the conjugate transpose     (complex-valued matrix entries), has its off-diagonal entries     bounded in absolute value by a so-called coherence parameter M. It     is desired that M be small, for example, M might be as small as     1/√n. In general, M cannot be zero because U cannot be a square     matrix, and so cannot be an orthogonal matrix. For a discussion of     coherence, see D. L. Donoho and X. Huo, IEEE Trans. Info Theory,     vol. 47, 2845-62. (2001) and D. L. Donoho and M. Elad, Proc. Natl.     Acad. Sci., vol. 100, pp 2197-2002, (2003).

Necessarily the representation A=UB indicated above is nonunique. However, the representation is very useful for designing CS matrices. A technique is disclosed herein for using this representation to obtain CS matrices.

Because of this non-uniqueness, it may be possible to obtain a CS matrix in which A can not be easily seen to have the desired structure. The assumed structure of the matrix allows a preferred way to generate CS matrices. However, the true criterion for CS matrices is whether they permit Compressed Sensing. A test is disclosed herein that allows one to check by a computer experiment whether a specific matrix A can be used in connection with the disclosed invention.

Additional properties of A are desirable in certain applications, but they vary from application to application, and are not strictly necessary to the invention. Examples include that the B factor is the matrix representation of a known digital transform, such as wavelet, Fourier, subband transforms, or that the U factor is part of a known transform, e.g. a selection of a subset of n rows of a known p times p matrix, such as the p times p Fourier matrix.

Reconstruction

Suppose now we have observed y—the vector based on n<m measurements—and wish to reconstruct x, the vector which could have been obtained based on m traditional measurements.

Ignoring noise for the moment, we are therefore trying to solve an underdetermined system of equations y=Ax for x, where both A and y are known. By standard ideas in Linear Algebra, it is known that this system of linear equations is underdetermined and so cannot have a unique solution in general. It would seem that we cannot hope to recover the m-vector x from the n-vector y reliably.

A driving property behind the disclosed approach is that the signals x of interest are compressible. This is a known property of standard images, medical images, spectra, and many other digital content types. The success of standard data compression tools such as JPEG, JPEG-2000, and MPEG-4. applied to such content types shows that wavelet transforms, local Fourier transforms and other transforms can all successfully compress such content types.

In a specific applications field, this compressibility has the following interpretation: Take n traditional measurements to obtain x. and apply a standard orthogonal transform B such as wavelets or local Fourier. The measured vector x would be compressed to a nearly sparse vector by the matrix B. That is, Bx would be a vector which can be well-approximated by a relatively small number of large-amplitude entries, with the remaining entries relatively small in amplitude (see S. Mallat, A Wavelet Tour of Signal Processing. Second edition. Academic Press (1999)).

The reconstruction technique herein disclosed exploits this property. It delivers, among approximate solutions y=Ax+e, an approximate solution x^(#) for which B x^(#) is sparse or nearly sparse. This goal of sparsity promotion can be attained by any of several embodiments.

Constructing CS-Matrices

As disclosed herein, there is an abundance of CS matrices and there are several natural methods to create them.

One preferred embodiment starts from a matrix B which sparsifies the content type of interest. For standard content types, B could be a discrete wavelet transform, a discrete Fourier transform, a discrete curvelet transform, discrete ridgelet transform, or other known mathematical transform. The key property that B must have is that for typical vectors x of the type we would like to make measurements about, the product θ=Bx is a vector which is nearly sparse. This means that, up to a tolerable approximation error, the vector θ has relatively few nonzero entries.

Once we have this matrix B, we create matrices A by the prescription A=UB, where U is one of the following preferred types of matrices:

-   1. Random n by p matrices with independent entries. Such matrices     have entries generated by a standard random number generator (see J.     Gentle, Random number generation and Monte Carlo methods, New York:     Springer (1998)). In a preferred embodiment, the random number     generator may have any of several distributions, all of which have     worked experimentally:     -   (a) Gaussian/Normal distribution. The numbers are generated with         the standard normal distribution having a probability density         with the familiar bell-shaped curve (see G. Seber, A. Lee,         Linear Regression Analysis, second edition. J. Wiley and Sons,         New York (2003); A. Gelman, J. Carlin, H. Stern, D. Rubin,         Bayesian Data Analysis, second edition. Chapman and Hall/CRC,         Boca Raton, Fla. (2004)).     -   (b) Random signs. The numbers are +1or −1with equal probability.     -   (c) Random sparse matrices. The numbers are +1or −1with         probability π each, or 0with probability 1-2π. Here π is a         parameter of the construction; it lies between 0and ½     -   (d) Random uniform numbers. The numbers are in the range −1to         1with equal density to every interval throughout this range         (see J. Gentle, Random number generation and Monte Carlo         methods. New York: Springer (1998)).

By random numbers we here intend that any of the standard sources of pseudo-random numbers can be used, i.e. of the kind that are common today in computer science. This does not rule out the use of true random numbers, produced by physical devices (see J. Walker, HotBits: Genuine random numbers, generated by radioactive decay. Fourmilab, Switzerland(1996)). This preferred list does not rule out other distributions of interest. The random number generators are preferred to be of the type that generate uncorrelated and, in fact, statistically independent random numbers, but other embodiments may be acceptable; see the next section.

-   2. Random Orthoprojectors. We generate a matrix V with standard     normal entries (as above), but in addition we orthogonalize the rows     of the matrix by a standard procedure, such as the Gram-Schmidt     procedure, producing a matrix U. The matrix U is an n-by-p matrix     which offers an orthogonal projection from R^(p) to R^(n). If the     random numbers were truly standard normal and independent to begin     with, then U is a uniformly distributed orthoprojector (se Y.     Baryshnikov, R. Vitale, Regular Simplices and Gaussian Samples.     Discrete & Computational Geometry 11: 141-147 (1994)). -   3. Partial Fourier Matrices. We generate an n by p matrix F with n     rows which are randomly sampled without replacement from among the p     rows of the orthogonal p by p Fourier matrix (see E. Candès, J.     Romberg, T. Tao, Robust Uncertainty Principles: Exact Recovery from     highly incomplete measurements. To appear, IEEE Transactions on     Information Theory (2004)). -   4. Partial Hadamard Matrices. We generate an n by p matrix H with n     rows which are randomly sampled without replacement from among the p     rows of the orthogonal p by p Hadamard matrix (see M. Harwit, N.     Sloane, Hadamard Transform Optics. New York: Academic Press (1979)).

This list has been chosen as teaching a practitioner skilled in scientific signal processing and computing one of several ways of obtaining a matrix U. Other methods are not precluded. Such other methods could include the use of various matrices from the theory of designs and codes; in the field of experimental design it is standard to create matrices X which are n by p where n is less than p and X′X has ones on the diagonal while X′X has off-diagonal entries bounded by M, for some small number M (see M. Harwit, N. Sloane, Hadamard Transform Optics . New York: Academic Press (1979); and N. Sloane, M. Harwit, Masks for Hadamard transform optics, and weighing designs. Applied Optics. Vol. 15, No. 1 (January 1976)). Any such matrix may be contemplated for use here, subject to verification.

Verifying CS-Matrices

It can be very important to check that a given proposed CS matrix really works. This means that it produces acceptable results for compressed sensing in a given application. We describe a way to validate performance below. This validation is important for two reasons: First, we just described ways to generate such matrices by using randomness. A side effect of using randomness is that occasionally, the matrices generated randomly do not have good properties, even though typically they do. Therefore, it is in principle always necessary to check performance. But in addition, many practitioners do not want to go to the time and effort of using true random numbers produced by physical randomness, and instead use computer-based pseudo-random numbers. The theory of randomness, strictly speaking, does not apply in this case. It would also be desirable to verify the CS properties when the preferred methods of generating a CS matrix described above have been avoided, in favor of other methods proposed by the user. Below we describe a computational experiment which the system designer may use to check if a proposed matrix really works.

Sparsity-Promoting Reconstruction Algorithms

A second ingredient for the invention is the reconstruction algorithm for obtaining an approximate reconstruction of x from the reduced-dimensionality measurement y. As described above, it should have the general property of being a sparsity promoting method: when there exists a solution x such that θ=Bx is nearly sparse, the methods should be well-suited to producing a sparse or nearly-sparse approximate solution. In the following list we describe several methods which have been found to offer the desired sparsity-promoting properties.

1. I₁ minimization. One solves the problem: min|Bx| ₁subject to y=Ax.

Here |.|₁ denotes the standard I₁ norm, or sum of absolute values. This is an I₁-minimization problem and can be implemented by a standard linear programming procedure, for example based on the simplex method (see G. Dantzig, Linear programming and extensions. Princeton, N.J.: Princeton University Press (1963)), on interior-point methods (see S, Boyd, L. Vandenberghe, Convex Optimization, Cambridge University Press (2002)), and on other algorithms for linear programming, such as iteratively-reweighted least-squares. Standard references in linear programming (see G. Dantzig, Linear programming and extensions. Princeton, N.J.: Princeton University Press (1963); and S, Boyd, L. Vandenberghe, Convex Optimization, Cambridge University Press (2002)) teach the practitioner how to solve such problems. Scientific papers, such as the authors' own publications, also do so (see S. Chen, D. Donoho, M. Saunders, Atomic decomposition by basis pursuit. SIAM Journal on Scientific Computing, 129- (1998)). The solution x^(#) to this problem is taken as the approximate reconstruction of x.

Alternatively, one solves the constrained optimization problem: min|Bx| ₁subject to |y−Ax| _(p) ≦t

Here |.|_(p) denotes an I_(p) norm, i.e. the p-th root of sum of p-th powers of absolute values, where 1≦p<

. The case p=∞ is also useful; if corresponds to |v|_(∞) max |v(i)| Valuable choices include an I₂ or an I_(□)norm. This is particularly useful in case our measurements y=Ax+z where z is a noise term. The parameter t has to do with the anticipated size of the noise z, i.e. t is chosen about the same size as |z|_(p).

This is a convex minimization problem and can be implemented by a standard convex programming procedure, for example based on the active-set methods, and on interior-point methods. Standard references in convex programming teach the practitioner how to solve such problems (see S, Boyd, L. Vandenberghe, Convex Optimization, Cambridge University Press (2002)). Scientific papers, such as the authors' own publications, also do so (see S. Chen, D. Donoho, M. Saunders, Atomic decomposition by basis pursuit. SIAM Journal on Scientific Computing, 129- (1998)). The solution x^(#) _(1,t) to this problem is taken as the approximate reconstruction of x.

Other variants are possible as well: min|Bx| ₁subject to |A′(y−Ax)|_(p) ≦t

This is again a convex optimization problem and can be computed using standard tools from the field of convex optimization. The solution can be used as an approximate reconstruction of x.

2. I₁ penalization. One solves the problem: min|Bx| ₁ +λ|y−Ax| _(p)

Here λ>0 is a regularization parameter to be chosen by the system designer.

This is a convex minimization problem and can be solved numerically by a standard convex programming procedure (see S. Chen, D. Donoho, M. Saunders, Atomic decomposition by basis pursuit. SIAM Journal on Scientific Computing, 129- (1998)). Other variants are possible as well: min|Bx| ₁ +λ|A′(y−Ax)|_(p)

This is again a convex optimization problem. In all cases an exact or approximate solution is taken as an approximation to the desired signal x.

3.. Stepwise Fitting. One can iteratively apply the procedure sometimes known as stepwise regression in statistics (see G. Seber, A. Lee, Linear Regression Analysis, second edition. J. Wiley and Sons, New York (2003)) or matching pursuit (see S. Mallat, A Wavelet Tour of Signal Processing. Second edition. Academic Press (1999))/orthogonal matching pursuit in signal processing. Starting from the definition r₀=y, one successively performs a series of steps. At the s-th step, s=1, 2, . . . , one:

-   -   (a) finds that single column of the matrix B A′ which has the         highest correlation with r_(s);     -   (b) orthogonally projects r_(s). onto that column leaving a         residual r_(s+1);     -   (c) checks if the current approximation is accurate; and     -   (d) if not, increments s by 1 and goes to (a).

This technique is well understood and taught in many sources in statistical modeling and in signal processing. There are four details of interest:

-   (1) the correlation measure discussed is the usual normalized inner     product<r_(s), c_(j)>/(|r_(s)|₂|c_(j)|₂) where c_(j). is the     j-column of BA′. -   (2) the orthogonal projection in step (b) can be onto the span of     the column identified at stage s, or onto the span of all columns up     to and including stage s. -   (3) the stopping rule in (c) can be based on statistical     considerations, e.g. reductions in residual sum of squares,     statistical significance of the F-to enter coefficient (see G.     Seber, A. Lee, Linear Regression Analysis, second edition. J. Wiley     and Sons, New York (2003)), etc., or based on the principle of     stopping after some given number of steps have passed. -   (4) It will be well-understood by a practitioner skilled in model     fitting that the process of successively subtracting fitted model     terms corresponds to a process of successively building up an     approximation a term at a time. Thus if the stepwise method stops at     stage s* which is much less than n, it implicitly produces a sparse     approximation. -   4. Stagewise Fitting.

One can iteratively apply the procedure sometimes known as stagewise regression in statistics or iterative hard thresholding in signal processing. Starting from the definition r₀=y, one successively performs a series of stages. At the s-th stage, s=1, 2, . . . , one:

-   -   (a) finds all columns of the matrix B A′ which have correlation         with r_(s) exceeding z/√n;     -   (b) orthogonally projects r_(s). onto those column leaving a         residual r_(s+1);     -   (c) checks if the current approximation is accurate; and     -   (d) if not, increments s by 1. and goes to (a).

There are four details of interest:

-   (1) the orthogonal projection in step (b) can be onto the span of     the columns identified at stage s, or onto the span of all columns     up to and including stage s.

(2) Strict orthogonal projection is not required, though it is recommended. Instead, one can use an iterative procedure which successively performs one-dimensional projections on different columns and subtracts them out either in parallel or sequentially. One can even perform such a procedure for a single iteration.

(3) The threshold z in (a) can be based on statistical consideration, e.g. the idea that correlations behave like standard normals with standard deviation 1/√n, or based on some empirical choice which works well in exeperiments.

(4) The overall procedure can be stopped when the residual correlations are consistent with a pure noise signal.

5. Alternating Projection methods. Other algorithms known to be useful in connection with sparse fitting may be useful here as well. These include the use of iterative solvers which successively approximate y by projecting residuals onto a sequence of constraint sets (nonnegativity, total variation, etc.), perhaps combined with a sequence of subspaces. Such methods are well-known in conjunction with signal processing and are taught in many sources (see C. Byrne, Iterative projection onto convex sets using multiple Bregman distances, Inverse Problems 15 1295-1313. (1999); and D. Youla, Generalized Image Restoration by the Method of Alternating Orthogonal Projections. IEEE Trans. Circuits and Systems, 25, No. 9 (1978)) Thus, we could try to find a vector x obeying simultaneously such constraints as x≧0, |y−Ax|₂≦t, Variation(x)≦C, by a process of alternately projecting the current residual on each component constraint set, subtracting the projection, obtaining a new residual, and continuing. Here Variation(x) means a discrete implementation of the bounded variation functional; this is discussed in numerous image processing publications (see L, Rudin, S, Osher, E, Faterni, Nonlinear total variation based noise removal algorithms, Physica D, 1992 (1992)), and is only listed here as an example.

6. Bayesian Modeling. By Bayesian modeling (see A. Gelman, J. Carlin, H. Stern, D. Rubin, Bayesian Data Analysis, second edition. Chapman and Hall/CRC, Boca Raton, Fla. (2004)), one can formally specify a probability model that makes x sparsely representable, for example by positing that Bx has a probability distribution such as Laplace or Cauchy, formally specifying that y=Ax+z with a formal noise model for z and then performing Bayesian inference for x. Such Bayesian methods are well-taught in numerous sources (see A. Gelman, J. Carlin, H. Stern, D. Rubin, Bayesian Data Analysis, second edition. Chapman and Hall/CRC, Boca Raton, Fla. (2004)). The only point of interest here is to use Bayesian methods which posit the underlying sparsity of x in some analysis framework Bx.

Variations

Several variations on the above ideas can widen the scope of applicability.

Subband Sensing

In some problems it is useful to view the object of interest x as a concatenation of several objects x₁,x₂,x₃, etc. and apply different measurement schemes for each one. For example, one could apply traditional measurement to x₁ but compressed sensing to x₂, etc.

To illustrate how this works, consider the case of subband decomposition (see S. Mallat, A Wavelet Tour of Signal Processing. Second edition. Academic Press (1999)) Common in signal processing is the notion of representing a signal or image x in terms of subbands with coefficient vectors x₁,x₂,x₃, . . . ; each vector represents that part of the signal in a given frequency band (see S. Mallat, A Wavelet Tour of Signal Processing. Second edition. Academic Press (1999)) Thus, in standard dyadic wavelet analysis the subbands consist of information at scales 1, ½, ¼. , etc., We can treat any one of the subband coefficient vectors x_(j) as the signal of interest. Suppose that such a set of coefficients has m_(j) entries and is defined in terms of the original signal via a subband operator S_(j); this has a representation as an m_(j) by m matrix x_(j)=S_(j)x. Design a CS matrix A_(j) associated with an n_(j) by m_(j) sized problem, using the techniques described in earlier parts of this disclosure. As it stands this matrix cannot be applied in the original sensing problem because the original object has dimension m. To apply it, we define a CS matrix C_(j). via C_(j)=A_(j). S_(j). The matrix C_(j) is n_(j) by m and can be used for compressed sensing of x_(j) on the basis of compressed measurements from the object x.

Postprocessing Noise Removal

It is sometimes the case that compressed sensing produces an approximation to the signal/image of interest, with an error that resembles noise. In such cases, it is possible to improve the quality of the reconstruction by applying some postprocessing: filtering to reduce the noise level. Any standard noise removal scheme, from simple running averages and running medians to more sophisticated wavelet denoising, may be applied (see D. Donoho, Denoising by soft-thresholding, IEEE Trans on Information Theory 41(3): 613-627 (1994); R. Coifman, D Donoho, Translation invariant denoising. In Wavelets and Statistics, Ed. Anestis Antoniadis Springer-Verlag Lecture Notes (1995); and D. Donoho, Compressed Sensing. To Appear, IEEE Trans. Information Theory (2004)).

Testing a CS-System

As indicated earlier, it is important to verify that a given matrix A actually offers compressed sensing. A method to do this is as follows:

Given the proposed matrix A, generate a suite of trial signals x₁, x₂, . . . x_(T), representing typical signals seen in practice in this application. For example this suite could consist of signals which were previously measured by traditional uncompressed sampling methods. For each trial signal x (say), generate a test dataset y=Ax (noiseless case) or y=Ax+z (noisy case). Run a sparsity-promoting reconstruction algorithm, for example, one of the algorithms mentioned above. Observe the output x^(#) of the algorithm and check either informally or by formal means that the output is of sufficiently high quality. If the result is judged to be of sufficient quality, then a successful CS-system is obtained. If not, generate a new candidate CS matrix and evaluate using the same empirical testing approach. Repeat this whole process of generating and testing candidate CS matrices several times if needed. If, at a given (n,m) combination, one does not succeed in finding a successful CS matrix A, then increase the value of n and repeat the same exercise.

EXAMPLE

FIG. 1 shows an example of compressed sensing in action. The signal Blocks, available in Wavelab (see J. Buckheit, D. Donoho, Wavelab and reproducible research in Wavelets and Statistics, Ed. Anestis Antoniadis Springer-Verlag Lecture Notes (1995)), has m=2048. and would traditionally need 2048. samples. However, Blocks is sparse when analysed in the Haar wavelet basis, essentially because of its piecewise constant character.

FIG. 1 shows the result of CS applied to this signal, with a matrix A having iid Gaussian entries, and using minimum I1. norm reconstruction. Even though only n=340. samples are taken, the result of length 2048. is perfectly reconstructed. That is, in this case, if we had shown both the original object and the reconstructed one, there would be no difference; hence we display on the reconstruction.

On the other hand, if only n=256. samples had been taken, the same approach would have given a noisy reconstruction, as can be seen from the second panel. This example illustrates that CS can work, but that there are definite limits to the power of CS. In this example, 6-to-1. reduction in the number of samples taken is successful, while 8-to-1reduction is less successful. By testing the system as recommended above, one can develop an understanding of the sampling rate required to get acceptable results in the application of interest.

The third panel of FIG. 1 also shows the result of post processing the noisy reconstruction based on n=256. samples using wavelet denoising. The visual appearance of the noise-filtered CS output seems improved and might be acceptable in some applications.

Technical Implementation

Exemplary Digital Data Processing Apparatus

Data processing entities such as a computer may be implemented in various forms. One example is a digital data processing apparatus, as exemplified by the hardware components and interconnections of a digital data processing apparatus.

As is known in the art, such apparatus includes a processor, such as a microprocessor, personal computer, workstation, controller, microcontroller, state machine, or other processing machine, coupled to a storage. In the present example, the storage includes a fast-access storage, as well as nonvolatile storage. The fast-access storage may comprise random access memory (“RAM”), and may be used to store the programming instructions executed by the processor. The nonvolatile storage may comprise, for example, battery backup RAM, EEPROM, flash PROM, one or more magnetic data storage disks such as a hard drive, a tape drive, or any other suitable storage device. The apparatus also includes an input/output, such as a line, bus, cable, electromagnetic link, or other means for the processor to exchange data with other hardware external to the apparatus.

Despite the specific foregoing description, ordinarily skilled artisans (having the benefit of this disclosure) will recognize that the invention discussed above may be implemented in a machine of different construction, without departing from the scope of the invention. As a specific example, one of the components may be eliminated; furthermore, the storage may be provided on-board the processor, or even provided externally to the apparatus.

Logic Circuitry

In contrast to the digital data processing apparatus discussed above, a different embodiment of this disclosure uses logic circuitry instead of computer-executed instructions to implement processing entities of the system. Depending upon the particular requirements of the application in the areas of speed, expense, tooling costs, and the like, this logic may be implemented by constructing an application-specific integrated circuit (ASIC) having thousands of tiny integrated transistors. Such an ASIC may be implemented with CMOS, TTL, VLSI, or another suitable construction. Other alternatives include a digital signal processing chip (DSP), discrete circuitry (such as resistors, capacitors, diodes, inductors, and transistors), field programmable gate array (FPGA), programmable logic array (PLA), programmable logic device (PLD), and the like.

Signal-Bearing Media

Wherever the functionality of any operational components of the disclosure is implemented using one or more machine-executed program sequences, these sequences may be embodied in various forms of signal-bearing media. Such a signal-bearing media may comprise, for example, the storage or another signal-bearing media, such as a magnetic data storage diskette, directly or indirectly accessible by a processor. Whether contained in the storage, diskette, or elsewhere, the instructions may be stored on a variety of machine-readable data storage media. Some examples include direct access storage, e.g. a conventional hard drive, redundant array of inexpensive disks (“RAID”), or another direct access storage device (“DASD”), serial-access storage such as magnetic or optical tape, electronic non-volatile memory, e.g. ROM, EPROM, flash PROM, or EEPROM, battery backup RAM, optical storage e.g. CD-ROM, WORM, DVD, digital optical tape, or other suitable signal-bearing media including analog or digital transmission media and analog and communication links and wireless communications. In one embodiment, the machine-readable instructions may comprise software object code, compiled from a language such as assembly language, C, etc.

Logic Circuitry

In contrast to the signal-bearing medium discussed above, some or all functional components may be implemented using logic circuitry, instead of using a processor to execute instructions. Such logic circuitry is therefore configured to perform operations to carry out the method of the disclosure. The logic circuitry may be implemented using many different types of circuitry, as discussed above.

Although the invention is described herein with reference to the preferred embodiment, one skilled in the art will readily appreciate that other applications may be substituted for those set forth herein without departing from the spirit and scope of the present invention. Accordingly, the invention should only be limited by the claims included below. 

1. A computer implemented method for designing special measurement matrices (CS-matrices) for use in compressed sensing, comprising the steps of: a processor generating a CS matrix A as a matrix product A=U B where B is p by m and U is n by p; a processor generating said matrix B with the property that, for objects of interest, Bx is sparse or is approximately a sparse vector, wherein B is an orthogonal matrix; and a processor generating said matrix U as an n by p matrix with the properties that: (1) the columns of U are of unit length in the Euclidean norm; (2) the square matrix G=U′U, where U′ denotes the transpose (real-valued matrix entries) or the conjugate transpose (complex-valued matrix entries), has its off-diagonal entries bounded in absolute value by the coherence parameter M; and a processor using said matrices to produce an approximate reconstruction of a digital signal or image.
 2. The computer implemented method of claim 1: wherein p is equal to m, so that B is a square matrix.
 3. The computer implemented method of claim 1: wherein said B factor is a matrix representation of a known digital transform, comprising any of a wavelet, Fourier, and subband transforms.
 4. The computer implemented method of claim 1: wherein said U factor is part of a known transform, comprising any of a selection of a subset of n rows of a known p times p matrix.
 5. A computer implemented method for constructing special measurement matrices (CS-matrices) for use with a compressed sensing scheme, comprising the steps of: a processor generating a matrix B which sparsifies a content type of interest, wherein B comprises any of a discrete wavelet transform, a discrete Fourier transform, a discrete curvelet transform, discrete ridgelet transform, or other known mathematical transform, wherein for typical vectors x, a product θ=Bx is a vector which is nearly sparse; and a processor creating matrices A by the prescription A=UB, where U comprises one of the following types of matrices: random n by p matrices with independent entries, wherein such matrices have entries generated by a standard random number generator, wherein said random number generator comprises any of the following distributions: Gaussian/Normal distribution, wherein numbers are generated with a standard normal distribution having a probability density with a familiar bell-shaped curve; random signs, wherein numbers are +1 or −1 with equal probability; random sparse matrices, wherein numbers are +1 or −1 with probability π each, or 0 with probability 1-2π, wherein π is a parameter of the construction, and lies between 0 and ½; and random uniform numbers, wherein numbers are in the range −1 to 1 with equal density to every interval throughout this range; random orthoprojectors, wherein a matrix V is generated with standard normal entries, but in addition the rows of the matrix are orthogonalized by a standard procedure, producing a matrix U., said matrix U comprising an n-by-p matrix which offers an orthogonal projection from R^(p) to R^(n); partial Fourier matrices, wherein an n by p matrix F is generated with n rows which are randomly sampled without replacement from among the p rows of the orthogonal p by p Fourier matrix; and partial Hadamard matrices, wherein an n by p matrix H is generated with n rows which are randomly sampled without replacement from among the p rows of the orthogonal p by p Hadamard matrix; and a processor using said matrices to produce an approximate reconstruction of a digital signal or image.
 6. A computer implemented method for verifying special measurement matrices (CS-matrices) for use with a compressed sensing scheme, comprising the steps of: a processor applying a sparsity-promoting reconstruction algorithm to obtain an approximate reconstruction of x from a reduced-dimensionality measurement y; a processor producing a sparse or nearly-sparse approximate solution when there exists a solution x such that θ=Bx is nearly sparse; wherein said sparsity-promoting reconstruction algorithm comprises any of I₁ minimization, I₁ penalization, stepwise fitting, stagewise fitting, alternating projection methods, and Bayesian Modeling; and a processor using said matrices to produce an approximate reconstruction of a digital signal or image.
 7. A computer implemented method for reconstructing a vector x representing compressible signals of interest, based on a vector y comprising n>m measurements produced by a compressed sensing scheme, comprising the steps of: a processor taking n traditional measurements to obtain x; a processor applying a standard orthogonal transform B; a processor compressing a measured vector x to a nearly sparse vector by said matrix B, where Bx is a vector which can be well-approximated by a relatively small number of large-amplitude entries, with remaining entries relatively small in amplitude; a processor delivering among approximate solutions y =Ax+e, an approximate solution x^(#) for which B x^(#) is sparse or nearly sparse; a processor applying post processing filtering to reduce a noise level; and a processor producing an approximate reconstruction of a digital signal or image. 